Review of Sc microalloying effects in Al-Cu alloys

Artificially controlling the solid-state precipitation in aluminum (Al) alloys is an efficient way to achieve well-performed properties,and the microalloying strategy is the most frequently adopted method for such a purpose.In this paper,recent advances in lengthscale-dependent scandium (Sc) microalloying effects in Al-Cu model alloys are reviewed.In coarse-grained Al-Cu alloys,the Sc-aided Cu/Sc/vacancies complexes that act as heterogeneous nuclei and Sc segregation at the θ′-Al_(2)Cu/matrix interface that reduces interfacial energy contribute significantly to θ′precipitation.By grain size refinement to the fine/ultrafine-grained scale,the strongly bonded Cu/Sc/vacancies complexes inhibit Cu and vacancy diffusing toward grain boundaries,promoting the desired intragranular θ′precipitation.At nanocrystalline scale,the applied high strain producing high-density vacancies results in the formation of a large quantity of (Cu Sc,vacancy)-rich atomic complexes with high thermal stability,outstandingly improving the strength/ductility synergy and preventing the intractable low-temperature precipitation.This review recommends the use of microalloying technology to modify the precipitation behaviors toward better combined mechanical properties and thermal stability in Al alloys.

Development in oxide metallurgy for improving the weldability of high -strength low-alloy steel-Combined deoxidizers and microalloying elements

The mechanisms of oxide metallurgy include inducing the formation of intragranular acicular ferrite(IAF)using micron-sized inclusions and restricting the growth of prior austenite grains(PAGs)by nanosized particles during welding.The chaotically oriented IAF and refined PAGs inhibit crack initiation and propagation in the steel,resulting in high impact toughness.This work summarizes the com-bined effect of deoxidizers and alloying elements,with the aim to provide a new perspective for the research and practice related to im-proving the impact toughness of the heat affected zone(HAZ)during the high heat input welding.Ti complex deoxidation with other strong deoxidants,such as Mg,Ca,Zr,and rare earth metals(REMs),can improve the toughness of the heat-affected zone(HAZ)by re-fining PAGs or increasing IAF contents.However,it is difficult to identify the specific phase responsible for IAF nucleation because ef-fective inclusions formed by complex deoxidation are usually multiphase.Increasing alloying elements,such as C,Si,Al,Nb,or Cr,con-tents can impair HAZ toughness.A high C content typically increases the number of coarse carbides and decreases the potency of IAF formation.Si,Cr,or Al addition leads to the formation of undesirable microstructures.Nb reduces the high-temperature stability of the precipitates.Mo,V,and B can enhance HAZ toughness.Mo-containing precipitates present good thermal stability.VN or V(C,N)is ef-fective in promoting IAF nucleation due to its good coherent crystallographic relationship with ferrite.The formation of the B-depleted zone around the inclusion promotes IAF formation.The interactions between alloying elements are complex,and the effect of adding dif-ferent alloying elements remains to be evaluated.In the future,the interactions between various alloying elements and their effects on ox-ide metallurgy,as well as the calculation of the nucleation effects of effective inclusions using first principles calculations will become the focus of oxide metallurgy.

Effects of Rare-earth and Microalloying Elements on the Microstructure Characteristics of Hypereutectoid Rails

We performed thermal simulation experiments of double-pass deformation of hypereutectoid rails with different microalloying elements at a cooling rate of 1℃/s and deformation of 80%to explore the influence of rare-earth and microalloying elements on the structure of hypereutectoid rails and optimize the composition design of hypereutectoid rails.Scanning electron microscopy,transmission electron microscopy,X-ray diffraction,and other characterization techniques were employed to quantitatively analyzed the effects of different microalloying elements,including rare-earth elements,on pearlite lamellar spacing,cementite characteristics,and dislocation density.It was found that the lamellar spacing was reduced by adding various microalloying elements.Cementite lamellar thickness decreased with the refinement of pearlite lamellar spacing while the cementite content per unit volume increased.Local cementite spheroidization,dispersed in the ferrite matrix in granular form and thus playing the role of dispersion strengthening,was observed upon adding cerium(Ce).The contributions of dislocation density to the alloy strength of four steel sheet samples with and without the addition of nickel,Ce,and Ce–copper(Cu)composite were 26,27,32,and 37 MPa,respectively,indicating that the Ce–Cu composite had the highest dislocation strengthening effect.The Ce–Cu composite has played a meaningful role in the cementite characteristics and dislocation strengthening,which provides a theoretical basis for optimizing the composition design of hypereutectoid rails in actual production conditions.

Enhancing corrosion resistance of ZK60 magnesium alloys via Ca microalloying: The impact of nanoscale precipitates

Enhancing corrosion resistance of Mg-Zn alloys with high strength and low cost was critical for broadening their large-scale practical applications. Here we prepared solutionized, peak-and over-aged ZK60 alloys with and without microalloying Ca(0.26 wt.%) to explore the effects of nanoscale precipitates on their corrosion behavior in detail via experimental analyses and theoretical calculations. The results suggested the peak-aged ZK60 alloy with Ca addition showed improved corrosion resistance in comparison with the alloys without Ca,owing to the contribution of Ca on the refinement of precipitates and increase in their number density. Although the precipitates and Mg matrix formed micro-galvanic couples leading to dissolution, the fine and dense precipitates could generate “in-situ pinning” effect on the corrosion products, forming a spider-web-like structure and improving the corrosion inhibition ability accordingly. The pinning effect was closely related to the size and number density of precipitates. This study provided important insight into the design and development of advanced corrosion resistant Mg alloys.

不同孕育剂随流孕育对微合金化球墨铸铁组织和性能的影响

为探究硫氧孕育剂随流孕育对微合金化球墨铸铁组织和性能的影响,在相同铸造条件下,用树脂砂型分别浇注75Si Fe孕育剂和硫氧孕育剂随流孕育处理的球墨铸铁试样。通过组织观察、室温拉伸试验、布氏硬度试验等分析了两种不同孕育剂随流孕育对微合金化球墨铸铁的显微组织、力学性能和拉伸断口的影响,探寻硫氧孕育剂随流孕育与球墨铸铁组织和性能的联系。结果表明:两种试样均由大量的珠光体、少量的铁素体、大量的石墨球组成,其中用75Si Fe孕育剂进行随流孕育,石墨球易畸变,圆整度不好,石墨球数量少,尺寸较大,平均球化率为84%,平均石墨球数为137个/mm^(2);而用硫氧孕育剂进行随流孕育,石墨形态改善明显,石墨球径更细小,分布更均匀,石墨球数量大幅增加,平均球化率为91%,平均石墨球数为297个/mm^(2)。硫氧孕育剂试样的抗拉强度和断后伸长率均高于75Si Fe孕育剂,分别为874 MPa和6.4%。硫氧孕育剂随流孕育球墨铸铁试样断裂模式为伴有少量塑性变形的准解理断裂。综合认为,用硫氧孕育剂随流孕育可获得较高的综合力学性能。

Ti微合金化热轧高强钢带性能试验研究

针对Ti微合金化高强钢带力学性能波动的问题,进行炼钢生产工艺优化,开展不同工艺对低合金高强钢热轧钢带力学性能影响的研究。原炼钢工艺为先将钢水在氩站进行钛合金化,然后直接送连铸机浇铸。为了进一步提高钢水洁净度、改善产品质量、增强力学性能稳定性,在原炼钢工艺中增加LF精炼工序,并进行新工艺试验。结果表明:钢水经过LF精炼处理,钢中硫含量从0.010%左右降低到0.005%左右,TiN夹杂物颗粒尺寸减小到10μm以内,能够使Ti微合金化高强钢热轧钢带的纵向冲击功提高43 J、横向冲击功提高38.9 J,并且具有良好的0℃低温冲击性能,保持产品力学性能稳定。

铒/钪-锆微量添加对Al-5Mg-3Zn合金热轧态组织和性能的影响

向Al-5Mg-3Zn合金中分别复合添加了锆(0.1%,质量分数,下同)和铒(0.2%)、锆(0.1%)和钪(0.2%),并进行热轧,研究了铒-锆、钪-锆微量添加对合金显微组织、拉伸性能和耐腐蚀性能的影响。结果表明:复合添加锆-铒或锆-钪元素能使合金热轧后保留更多变形组织,抑制合金的动态再结晶,且锆-钪元素的抑制作用强于锆-铒;热轧态Al-5Mg-3Zn合金晶内出现少量尺寸较大的T相,热轧态Al-5Mg-3Zn-0.2Er-0.1Zr、Al-5Mg-3Zn-0.2Sc-0.1Zr合金晶内除了T相,还分别存在Al3(Er,Zr)相和Al3(Sc,Zr)相,3种试验合金晶界处均无析出相和沉淀析出带;相比热轧态Al-5Mg-3Zn合金,热轧态Al-5Mg-3Zn-0.2Er-0.1Zr合金抗拉强度、屈服强度分别提升了9.3%,34.3%,热轧态Al-5Mg-3Zn-0.2Sc-0.1Zr合金分别提升了24.8%,35.6%;3种热轧态试验合金均保持良好的耐腐蚀性,热轧态Al-5Mg-3Zn合金的耐腐蚀性能更优。

Ce微合金化在镁合金中的研究现状与展望

Ce微合金化是开发低成本、高性能镁合金的一种有效途径,对我国镁资源的循环利用和可持续发展具有重要的意义。本文综述了近五年来Ce微合金化在镁合金中的研究进展,分别讨论了Ce微合金化对Mg-Al、Mg-Zn、Mg-Gd、Mg-Y系列合金的微观组织、时效析出行为、织构演变以及力学性能的影响。为建立含Ce镁合金中成分与力学性能间的关系提供了数据支持。此外,还详细阐述了Ce的添加对提高镁合金耐蚀性的强化机理。最后指出了Ce微合金化在镁合金应用中目前面临的一些问题和思考,提出了进一步深入研究的几个方面,以期拓宽轻量化稀土镁合金的应用范围。

微量Ca对ZE22镁合金显微组织及加工硬化行为的影响

为改善ZE系列镁合金延展性及加工性能,以ZE22为基础合金,通过Ca微合金化改善其加工硬化能力。进行EBSD及室温拉伸试验,研究微量Ca对ZE22镁合金显微组织及加工硬化行为的影响。结果表明:微量Ca的加入可细化晶粒,使平均晶粒尺寸为6.38~8.44μm,并引起基面织构弱化,织构极强度从22.3降至19.2,提高了基面滑移系的施密特因子。微观分析发现,加工硬化的弱化是晶粒尺寸和织构双重作用的结果。微量Ca的加入使合金加工硬化能力和应变率敏感系数降低,ZEG220合金的强塑性匹配更佳。研究结果为微合金化调控镁合金的加工硬化能力提供了理论基础和指导。

Al/Ti对Cu-10Ni合金耐冲刷腐蚀性能的影响

研究微合金化对Cu-10Ni合金耐3.5%NaCl溶液冲刷腐蚀的影响。使用中频真空熔炼炉熔炼Cu-10Ni-1Fe-1Mn-X(X=0.2Al或0.2Ti)合金,使用相同的热处理及冷变形工艺制备样品后与Cu-10Ni合金一起进行冲刷腐蚀实验。通过扫描电子显微镜(scanning electron microscope,SEM)、 X射线衍射仪(X-ray diffractometer, XRD)、电化学腐蚀、电化学阻抗谱(electrochemical impedance spectroscopy,EIS)、X射线光电子能谱仪(X-ray photoelectron spectrometer,XPS)、质量损失测试等对样品进行分析表征。结果表明:加入0.2Al/0.2Ti后的Cu-10Ni合金的耐冲刷腐蚀能力得到提高。这是由于在Cu-10Ni-0.2Al合金及Cu-10Ni-0.2Ti合金表面耐腐蚀膜中分别含有Al_(2)O_(3)、TiO_(2),提高了样品的耐冲刷腐蚀能力;Cu-10Ni-0.2Ti合金耐冲刷腐蚀能力略强于Cu-10Ni-0.2Al合金的,这是因为Cu-10Ni-0.2Al合金在Cl^(-)富集的环境中易吸收Cl^(-),从而导致膜层有一定的裂纹。

钛微合金化高强钢的连续冷却相变规律

为了研究钛微合金化高强钢在连续冷却条件下的相变规律,通过热膨胀法及金相分析研究了低碳钢(C-Mn钢)和钛微合金钢(Ti钢)在连续冷却过程中的组织变化及过冷奥氏体的相变规律,分析了钛元素和变形对试验钢相变规律的影响,并讨论了连续冷却转变(CCT)与等温转变(TTT)曲线的关系。结果表明:随着冷速的增加,试验钢的主要相变组织由铁素体向贝氏体转变。在C-Mn钢中加入钛元素提高了过冷奥氏体的稳定性,抑制了铁素体和珠光体转变,促进了贝氏体转变;在奥氏体未再结晶区进行变形使试验钢的CCT曲线整体向左上方移动,提高了相变开始温度;变形提高了铁素体的形核率,促进了铁素体相变,铁素体组织得到细化;变形促进了贝氏体相变,使板条贝氏体变短,细化贝氏体组织。

铌微合金化和淬火速率对热成形钢组织与力学性能的影响

基于传统22MnB5钢设计了一种新型含Nb热成形钢,研究在不同淬火速率下Nb对热成形钢显微组织与力学性能的影响。新型Nb微合金化热成形钢与广泛应用的22MnB5商业钢种均经900℃保温3 min的固溶处理后分别水淬和油淬至室温,检测两种钢在两个淬火条件下的力学性能,并通过扫描电镜、背散射电子衍射仪、X射线衍射仪和透射电镜等分析合金组织。结果表明:油淬时Nb微合金化热成形钢与22MnB5钢能发生较明显的自回火,但前者的屈服强度高于后者约130 MPa,且伸长率也略有改善,对强化机制的定量计算表明这是由于含Nb钢晶粒细化形成的细晶强化以及位错强化和沉淀强化的共同作用;而在水淬条件下,两种钢的屈服强度与伸长率均相似,推测是由于冷却速率高抑制了自回火,使得马氏体相变产生的残余应力成为影响屈服强度的主导因素,而当水淬样品在170℃回火减轻内应力后,此时含Nb钢屈服强度再次高于22MnB5钢。

铬含量对Al-Cu-Mg-Ag合金微观组织和热暴露性能的影响

研究了Cr含量对Al-Cu-Mg-Ag合金微观组织和热暴露性能的影响。结果表明,随着Cr含量增加,合金室温强度呈先上升后下降的变化趋势,含0.2%Cr的合金表现出优异的室温力学性能。透射定量计算结果表明,向合金中添加0.2%Cr,促进了热暴露后合金中Ω相的析出,提高了Ω相的抗粗化性能。Cr添加量超过0.3%后,合金晶界处析出(Al,Cr,Mn,Ti)富集相,导致晶粒粗大。

冷却速度对Ti微合金化Q355B屈服平台的影响研究

为了研究冷却速度对Ti微合金化Q355B屈服平台的影响,选取某钢厂Q355B-Ti热轧钢卷,在终轧温度和卷取温度不变的情况下,分别测定在12℃/s、13℃/s、14℃/s、16℃/s、18℃/s、21℃/s、26℃/s、30℃/s冷却速度下拉伸性能曲线和金相组织。结果表明,冷却速度在12~16℃/s区间时无明显屈服平台,18~30℃/s区间时产生屈服平台,金相组织为贝氏体+铁素体,随着冷速增大,贝氏体组织形貌由不规则羽毛状向规则多边形转变,晶粒尺寸减小,晶粒度由10级增大到11级。分析认为,Q355B-Ti热轧钢卷产生屈服平台需要冷却速度达到18℃/s的临界值,在工艺设计范围内,通过控制冷却速度可以达到抑制或促进屈服平台的产生。

交通运输用导电铝合金的应用现状及研究进展

随着经济社会的不断发展,城市轨道交通建设以及电动汽车、新能源交通工具的逐渐普及,铝合金导线在交通运输网络的电力传输和交通装备运行等方面的用量日益增多,但铝合金导线因其本征的电阻在电力传输过程中仍存在着很大程度的能源损耗,如何提升导电率的同时保证铝合金导体材料的强度是研究的长期难点。本文结合导电铝合金的发展现状及主要合金体系,探讨了铝合金导体材料的强度-电导率制约关系,总结了当前协同改善强度和导电率、制备高强高导铝合金的研究进展,归纳了几类主流的改善方法,即微合金化、热处理工艺优化、大塑性变形制备超细晶、制备铝基复合材料、熔体净化和提纯、沿平行电流方向引入细长晶等,最终展望了高强高导铝合金的未来发展。

Mo微合金化对82B钢高温力学性能及显微组织的影响

研究了添加Mo(质量分数)为0.02%、0.04%、0.07%、0.11%的82B钢对不同温度下高温拉伸后的组织和性能的影响及Mo对82B高碳钢的强韧化机理。结果表明:(1)200~300℃高温拉伸时,4组试验钢力学性能较好,300℃达到峰值,Mo为0.11%试验组最优,抗拉强度由1139 MPa增至1192 MPa,屈服强度为736 MPa,略有降低,伸长率与断面收缩率均有显著提高,分别为22%和72.9%。相较于Mo为0.02%试验钢,虽屈服强度下降约5%,但抗拉强度升高5%,伸长率、断面收缩率大幅增加,且塑性随Mo含量同步提高,随着温度继续升高,由于材料开始软化,各项力学性能均呈下降趋势。(2)Mo为0.02%和0.04%时,显微组织除渗碳体随拉伸温度的提高逐渐增多外,索氏体与珠光体未出现明显变化,与室温相同,当Mo增至0.07%和0.11%时,索氏体、珠光体团逐渐细化且分布均匀。同时,4组试验钢在300℃高温拉伸时出现蓝脆现象,通过断口观察发现,有Al、Si等元素的夹杂物存在,且失效方式为韧性断裂,断口主要可分为剪切唇区和纤维区,剪切唇区的面积随着温度的升高逐渐缩小。

氮含量与终轧温度对钛微合金化高强钢CGLC700低温冲击韧性的影响

针对钛微合金化高强钢CGLC700低温冲击韧性差的问题,通过热力学计算与高温原位观察,采用电子背散射衍射、透射电镜、扫描电镜和光学显微镜对含Ti高强钢的夹杂物、第二相粒子、断口形貌和低温冲击韧性等进行了研究。结果表明,含Ti高强钢低温冲击韧性差的原因与钢中大尺寸脆性夹杂物和Ti(C,N)、TiN析出相有关。将钢中w[N]从0.0049%降低至≤0.0035%时,可以有效降低钢中脆性夹杂物的数量和尺寸,从而提高钢材冲击韧性;终轧温度从885~895℃降低至875~885℃,可以促使纳米级TiC第二相粒子析出和大角度晶界的生成,并降低有效晶粒尺寸,从而明显改善钢材的低温冲击韧性;同时降低氮含量至≤0.0035%与终轧温度在875~885℃时,钛微合金化高强钢中平均晶粒尺寸从3.1μm降至2.7μm,小尺寸有效晶粒占比高,大尺寸夹杂物及数密度降低,大角度晶界中占比增长了16.6%,钢材低温冲击功可以从14.75 J提高到37.35 J。

基于电子结构理论的微合金Q355B热轧钢力学性能预测

基于固体与分子经验电子理论(EET),结合微合金Q355B钢的化学成分,计算合金电子结构参数特征值。在传统合金电子结构模型基础上,引入铁素体体积分数、珠光体的晶粒尺寸和体积分数、珠光体片层间距等进行模型修正,提出新的预测模型。从细晶强化、固溶强化、相界面强化、析出强化以及珠光体相变强化入手,建立了微合金Q355B热轧钢的力学性能预测模型,并分别计算了抗拉强度、屈服强度、延伸率和冲击功。将传统模型和本模型的计算值与试验值进行对比,结果表明,修正后的模型对抗拉强度、屈服强度、延伸率和冲击功的预测相对误差分别为0.07%、0.84%、6.27%和3.40%,绝对误差分别为0.4 MPa、3.9 MPa、1.7%和1.1 J。与传统模型相比,本模型对强度的预测结果十分精准,对延伸率和冲击功的预测精度有较大提升,表明本模型的预测结果更接近试验值。

Ca、Sr微合金化对Mg-3Zn合金显微组织与力学性能的影响

利用坩埚式电阻炉制备了Mg-3Zn-xCa-ySr合金(x=0、0.1、0.3,y=0.1、0.3),采用光学显微镜(OM)、X射线衍射仪(XRD)、扫描电镜(SEM)研究了Ca元素和Sr元素对Mg-3Zn合金显微组织和力学性能的影响。结果表明:向Mg-3Zn-0.1Sr合金加入微量Ca时合金组织有小幅细化,大幅提高了合金力学性能;Ca元素含量达到0.3%时,合金出现Mg_(2)Ca相,连续分布在晶界上,对屈服强度影响不大,小幅降低了合金抗拉强度和塑性。在Ca含量为0.1%时,随着Sr含量的增加,合金晶粒细化,第二相增多,在晶界上生成新相Mg_(17)Sr_(2),抑制了细晶强化的效果,使合金屈服强度和抗拉强度变化不大,但塑性显著提升,此时合金综合性能最优。

微合金钢等温过程中带状组织演变规律研究

采用热模拟试验机、金相显微镜和扫描电镜研究了微合金钢在等温过程中的带状组织演变规律,并对其形成机理进行了分析。结果表明:试样在650~700℃等温时,带状组织为铁素体/马氏体。在550~600℃等温时,带状组织为针状铁素体/马氏体,且随着等温温度的下降,针状铁素体的体积分数不断升高。Mn的带状偏析是导致该等温期间不完全转变现象的根本原因。当等温温度降到450℃时,组织全部为针状铁素体,带状组织基本消失。